Load-absorbent device for introducing load forces such as cable forces or tensioning forces of sheet-like structures

ABSTRACT

A load-absorbing device for initiating load forces such as cable forces or tensioning forces of sheet-like structures into supporting structures ( 10 ), with at least one bearing element ( 24, 80 ) which is anchored on the respective supporting structure ( 10 ) and to which a tie rod ( 40 ) of a load-absorbing part ( 36, 40 ) is connected, and with a connection device ( 50 ) for tension members ( 16; 98 ) which cooperates with the tie bar ( 40 ), is characterized in that the connection device ( 50 ) has at least one connection wing ( 66 ) which projects laterally from the longitudinal axis (A) and which forms at least one connection point ( 69   a ) offset with respect to the longitudinal axis (A).

The invention relates to a load-absorbent device for introducing load forces, such as cable forces or tensioning forces of sheet-like structures, into supporting structures and that comprises at least one bearing element which is anchored to the pertinent supporting structure and to which a tension rod of a load-absorbent part is connected, and that comprises a connecting device for tensioning members which interacts with the tension rod.

Modern architecture has increasingly incorporated concepts of load-bearing structures, where planar elements, such as tent-like or umbrella-like coverings that form, as a textile building material, part of a load-bearing structure, are anchored or erected on support systems, for example, steel supports. In order to achieve that the respective elements form space-creating structures of a desired architectural design, the respective suitable introduction of load forces, in particular, the tensioning or bearing cable forces, is a crucial factor. To avoid distortions of the desired architectural design, it is conventional to brace the surface elements on a plurality of connecting points. A corresponding plurality of tensioning members such as tensioning cables must therefore be attached to a corresponding number of load-absorbing devices; this leads to considerable installation effort, especially since pertinent bearing elements may not be comfortably accessible on the support system of the supporting structure, such as, for example, supports, with varying inclination.

In light of the foregoing, the object of the invention is to provide a load-absorbing device of the indicated type which with a simple design enables reliable connection of tensioning members to the tension rod with low installation effort.

The invention achieves this object with a load-absorbing device which has the features of claim 1 in its entirety.

According to the characterizing part of claim 1, an essential particularity of the invention is that the connecting device has at least one connecting wing which projects laterally from the longitudinal axis and which forms at least one connection point which is offset to the longitudinal axis. Compared to a coaxial connection of tensioning members, such as cables or brackets or the like, to a tension rod, the connection to a laterally projecting component is much simpler, both with respect to the installation effort and also the use of the required connecting means.

The arrangement can be especially advantageously made such that the respective wing is supported on the tension rod to be able to swivel around the longitudinal axis. Regardless of the respective circumstances, the connection point can thus be moved into the position which is especially suitable for the installation process while, at the same time, the connection point can be set into the optimum swivel position under the action of the tensioning force.

In especially advantageous exemplary embodiments, the connecting device has two wings which extend in different directions away from the longitudinal axis. Exemplary embodiments of this type in an especially advantageous manner enable the connection of several tensioning members to a common load-absorbing member.

The arrangement can be made especially advantageously such that the two wings are formed by plates of the same shape and are rigidly connected to a hinge member which forms the swivel bearing of the pertinent wing on the tension rod. For connection points which are formed on laterally projecting plates, not only is the coupling of the tensioning cables made simple, reliable, and convenient, but this type of construction is also especially suited to mounting tent-like or sail-like surface supporting structures in which there is no securing at points, but which are mounted on edge regions with, as it were, “linear fastening.” In these cases, the pertinent sheet-like supporting structure (tent, sail, or membrane) on the edge is provided with a keder. In the connecting sections, this keder is surrounded by a keder groove profile which holds it and which can be connected in turn to the pertinent load-absorbing member, that is, the assigned tension rod. This can take place especially advantageously such that the plates which form the connecting wings at the connection points form linkage sites for tension brackets which on the other hand are connected to linkage sites on the pertinent keder groove profile which are located at a mutual distance from one another.

The hinge member which forms the swivel bearing of the wings on the tension rod can be constructed as one piece and can horizontally connect the wings rigidly to each other in a common plane.

Alternatively, another possibility for equalization or setting movements can be that the hinge member is multi-part and for each wing has one bearing part with which the wings can be swiveled around the longitudinal axis independently of each other.

As another configuration, it can be provided that the respective wing be supported on the hinge member to be able to swivel around another axis which is perpendicular to the swiveling axis of the hinge member which corresponds to the longitudinal axis of the tension rod.

In exemplary embodiments in which the tension rod has an external thread on which an adjusting nut forms an axial safeguard of the connecting device, the additional advantage is that by actuating the adjusting nut, a turnbuckle-like tensioning or retensioning of the connecting device and in turn of the respective pertinent tensioning members is made possible.

Regardless of the configuration of the connection to one or to two connecting wings, rigid connection of connecting wings, or individual or joint swiveling capacity of the respective wings around the longitudinal axis of the tension rod, a spherical body attached to the tension rod for forming a hinge joint on the bearing element can be supported on a support surface which forms one part of a spherical cap so that a ball-and-socket joint is formed on the bearing element.

Additional advantages, features, and details of the invention are apparent from the following description of preferred embodiments as well as by means of the drawings. These drawings show in

FIG. 1: a perspective oblique view of a roof covering composed of a sail, which is mounted between four columns and is also referred to as a roof membrane;

FIG. 2: a perspective oblique view of a hinge holder or joint, which is mounted on the apex or head surface of a column of FIG. 1 and which secures the sail on the column;

FIG. 3: a perspective view of the disassembled hinge holder of FIG. 2 with its assigned insert screw or rotary screw as well as with an end disk of the column;

FIG. 4: a side view of the assembled hinge holder of FIG. 3 with an inserted insert screw;

FIG. 5: the front view of the hinge holder;

FIG. 6: the rear view of the hinge holder;

FIG. 7: the top view of the hinge holder;

FIG. 8: the top view of a base plate of the hinge holder of FIGS. 3, 6;

FIG. 9: a sectional view of FIG. 7 along its line IX-IX;

FIG. 10: a perspective oblique view of the hinge holder of FIG. 2;

FIG. 11: a side view of FIG. 10;

FIG. 12: a sectional view of FIG. 10 along the line XII-XII of FIG. 7;

FIG. 13: a perspective view of a modified, disassembled hinge holder with its assigned insert or rotary screw as well as with the indicated end region of the column;

FIG. 14: the top view of the assembled hinge holder of FIG. 13;

FIG. 15: a sectional view of FIG. 14 along its line XV-XV;

FIGS. 16 to 18: the front and the rear view of the hinge holder of FIGS. 13 to 15 and a perspective oblique view of the same;

FIG. 19: a hinge holder on the end of a horizontally extending column in an oblique perspective side view;

FIGS. 20, 28, and 30: in each case a perspective oblique view of the respective other embodiments of a hinge holder;

FIGS. 21 and 31: a front view of FIGS. 20 and 30, respectively;

FIGS. 22 and 33: a sectional view of FIG. 21 along its line XXII-XXII and of FIG. 31 along its line XXXIII-XXXIII;

FIGS. 23, 29, and 32: a top view of the hinge holder of FIG. 20 and FIG. 28 and FIG. 30, respectively;

FIG. 24: a sectional view of FIG. 23 along its line XXIV-XXIV;

FIGS. 25 and 34: a perspective oblique view of a front plate according to FIG. 20 and according to FIG. 30, respectively;

FIGS. 26 and 35: a front view of FIG. 25 and FIG. 34, respectively;

FIGS. 27 and 36: a top view of FIG. 25 and FIG. 34, respectively;

FIGS. 37 and 48: a perspective oblique view of a holding plate, which consists of two connecting plates and is connected with the insert screw of the hinge holder by means of a base hinge;

FIG. 38: one of the connecting plates of FIGS. 37, 48 in an oblique view;

FIG. 39: a connecting plate, which is designed differently from that in FIG. 38;

FIGS. 40 and 49: a perspective view of a part of the base hinge of FIGS. 37 and 48,

respectively;

FIGS. 41 and 50: a front view of FIGS. 40 and 49, respectively;

FIGS. 42 and 51: an enlarged detail of FIG. 41 according to its region XLII and FIG. 50 according to its region LI;

FIG. 43: a top view of a part of FIG. 37;

FIG. 44: a front view of FIG. 43;

FIGS. 45 to 47: in each case a perspective oblique view of the hinge holder of FIG. 2 in different positions;

FIG. 52: a front view of FIG. 53;

FIGS. 53 and 54: in each case a top view of a part of FIG. 48;

FIG. 55: a perspective oblique view of a connecting member with an attached additional strip consisting of two adjacent angle sections;

FIG. 56: a disassembled perspective view of the arrangement according to FIG. 55;

FIG. 57: an enlarged side view of an angle section of FIGS. 55, 56;

FIG. 58: the angle section as depicted in FIG. 57 with an attached top;

FIGS. 59 and 60: in each case an enlarged cross-sectional view of FIG. 58 according to its regions LIX and LX, respectively;

FIG. 61: a perspective oblique view of two strips that are assigned to each other;

FIG. 62: an installation drawing of FIG. 61 with its strips in front view;

FIGS. 63 and 64: in each case a disassembled perspective view of two additional arrangements;

A plane load-bearing structure has, according to FIG. 1, four somewhat outwardly inclined columns 10, which are set apart from each other and reach upward in pairs from a floor area B and stretch between their free ends 11 a sail S, which has an approximately rectangular contour and is made of a textile material, as a membrane-like roof surface. On the other hand, those free ends 11 are tensioned by cables 14 against the floor area B and anchors (not illustrated herein) that are secured on the latter. The four corner regions of this membrane S or a correspondingly constructed net are connected in each case by short cable strands 16 to so-called hinge joints 20, which project from the head surface 12 _(k) of the column 10. The head surface 12 _(k) forms the upper edge of the supporting structure and is formed by an end disk 12, which is inserted into the column 10.

According to FIGS. 2 and 3, a base plate 22 having a diameter d of, for example, 117 mm and a height h of, for example, 20 mm, of the hinge joint 20 has a bearing element 24, which has an angular configuration in FIGS. 7 and 14 and a height h₁ of 100 mm and a thickness e of approximately 37 mm, with two molded-on leg sections 25, 25 _(a). The latter form a two-armed configuration having an angle w of approximately 120°, as shown in the top view of FIG. 7.

It is very clear from the FIGS. 3, 5, and 6 that two side surfaces 27 of a width e extend from a ridge surface 26 of the bearing element 24. The upper top region of said side surfaces is slightly curved in the direction of the ridge surface 26. The width of the connecting region 25 _(q) of the two curved sections 25, 25 _(a) in the ridge surface 26 is designated as e₁ in FIGS. 7 and 12.

The ridge surface 26 and each of the side surfaces 27 define outwardly a wall region of the hinge joint 20 or more specifically the bearing element 24 that exhibits a curved longitudinal cross section. A relatively large aperture 30 is milled into the center of said bearing element as well as axially in relation to the central axis M of the hinge joint 20. The edge 32 of said aperture runs at an axial distance a of about 10 mm in relation to the planar ridge surface 26. The distance h₂ between the center Z of the aperture and the base plate 22 measures approximately 50 mm. Moreover, due to the milling and the angular configuration of the bearing element 24, that edge 32 is slightly curved in the cross section and defines a surface region 31 of the hinge joint 20. This surface region 31 is matched to a part of the surface of a bearing ball 36 (described below) that is capable of resting flush with the surface region 31 in the tensioning direction that is indicated with an x (FIGS. 2, 11, 14, 55). The forces are transferred to the bearing element 24 by way of the engagement surface.

Between the pair of curved sections 25/25 _(a), there is a triangular surface section of the head surface 23 of the base plate 22, which surface section is triangular in shape in the top view; and its central region shows a screw hole 29 for a connecting screw 21. FIG. 8 shows the position of two additional screw holes 29 in the base plate 22, one of the screw holes lying in the transverse axis Q of the base plate, and the two others lying on both sides of said transverse axis at distances a₁ from it of approximately 28 mm. Each screw hole 29, having a diameter i of 17 mm herein, passes over in the direction of the upper surface 23 of the base plate 22 into a funnel-shaped expansion 29 _(t) having an upper surface diameter i₁ of 29 mm.

The dimensions of all of the parts of the hinge joint 20 are adjusted to the respective cable forces that may arise; that is, the securement elements that are designed to meet static requirements can be matched to a plurality of cables 14. Below are listed the dimensions for forces that may occur, for example, at a pointwise attachment having a tensioning force of approximately 100 kN.

FIG. 10 depicts the rotary screw 40 in the horizontal position as well as two of the three connecting screws 21, which approximately flank the curved section 25 _(a).

The connecting screws 21, shown at the upper end in FIG. 3, in the attachment position, extend into the screw holes 29 _(e) of the end disk 12 of the column 10.

In the working position, the aforementioned bearing ball 36 having a diameter d₁ of approximately 74.5 mm herein sits in the aperture 30 of the bearing element 24. In the example according to FIGS. 11 and 12, this bearing ball 36 is provided with a surface 35 and a radial passage 37. The surface 35 serves as the stop face for the head 38 of a rotary screw 40 having a diameter f of 26 mm. The reference numeral 39 shows a washer assigned to the head 38. According to FIG. 12, the longitudinal axis A of the rotary screw 40 of the bearing ball 36 is to be rotated with the said bearing ball at an angle w₁ of approximately 80° (swivel level A₁ of the longitudinal axis A of the screw). Likewise, it is clear that the bearing ball 36 can be swiveled horizontally; that is, the possibilities of the directions of the bearing ball 36 in the bearing element 24 describe a conical shape.

FIG. 3 shows an inventive hinge joint 20 with the connecting member 50, which is also shown in FIG. 2, as individual parts for the sake of a better overview. It is clear that the rotary screw 40 passes through the plate-like connecting member 50, which is fixed in position by a nut 41, supported on a washer 39, and which is described in detail below.

The hinge joint holder 20 of FIGS. 13 to 19 accommodates a bearing ball 36 _(a) in its aperture 30 _(a). The rotary screw 40 in this bearing ball extends into a blind hole 34 with an internal thread, that is, does not totally pass through this bearing ball 36 _(a).

FIG. 19 offers a horizontal column 10 _(a) as a variation. Arranged in parallel to the longitudinal axis E of this column, a protruding support tongue 42 with its position stabilizing support consoles 43 is molded to said column. The base plate 22 of the hinge joint 20 sits on this support tongue 42; and, in this case, the rotary screw 40 and, thus, also the connecting member 51 run parallel to the longitudinal axis E, that is, also horizontally. Each of the side edges of the connecting member 51 has a threaded fitting 70, which is described in detail with respect to FIG. 39.

FIG. 20 shows a cassette-like or sleeve-like body 80, which can be secured, for example, on a wall area F with retaining screws 18. The screw holes for these retaining screws are marked with the reference numeral 19. It is also clear that this body 80 has two plates 82, which protrude in parallel from a rear wall 81 having a height h₄ of 100 mm. The said plates have a width b₃ of 140 mm and an overhang length n₁ of 120 mm and a thickness e₄ of 20 mm. In this case, the height h₅ of the interior space 79 of this body 80 also measures 100 mm. Between the free ends of those plates 82 there is a front plate 84 of a height h₅ that contains the above-described aperture 30 with the matching surface region 31. The aperture 30 of the front plate 84 can accommodate the described bearing ball 36, herein without the rotary screw. FIGS. 25 to 27 show the shape of this front plate 84 with the inwardly shaped side wall surfaces 85 as well as a horizontal cross section that tapers off in the direction of the central axis G of the front plate 84. The ridge surface 86 is constructed accordingly (FIG. 27).

This front plate 84 can also be inserted into a body 80 _(a) that has asymmetrical overhang plates 83 (see FIGS. 28 and 29). In the top view, each of the said overhang plates is provided with an overhang tongue 88 on a side surface, the distance n₂ between the overhang tongue and the rear area of the rear wall 81 being greater than the length of the other longitudinal side 87. In this case, the transversal distance b₄ between the said longitudinal side 87 and the overhang tongue 88 is 92 mm.

FIG. 30 shows a totally different design concept of the wall joint 90. Two console plates 93 having an overhang length k of 48 mm project frontward at a distance h₇ of 70 mm from a rear plate 92 having a height h₆ of 150 mm, a width b₅ of 66 mm, and a thickness e₄ of 10 mm. The rear plate 92 is secured with retaining screws 18 on a wall that is not illustrated herein.

Each of the console plates 93 that resemble tongues in the top view has a hole 94 for a connecting screw 21 _(a) in the central axis T of said console plates. The latter screw secures an annular retaining body 96 of the wall joint 90 between the console plates 93; and said retaining body holds a bearing ball 36 _(a) in a central aperture 30.

The aperture 30 is centered in relation to the retaining body 96, having a height h₅ of 70 mm, a thickness e₆ of 31 mm, and a width b₃ of 54 mm, the center of the aperture also being marked with the reference symbol Z.

The connecting member 50 referred to with respect to FIGS. 2 and 3 and having a width n of 120 mm projects in a wing-like manner from the rotary screw 40 with a head 38 against which the connecting member 50 rests. The rotary screw 40 passes through a central base hinge 52, which is composed of two hinge halves 54, 54 _(a), each of which has a tubular part 56 having a width e₂ of 40 mm, according to FIG. 40, with a tubular channel 57 having a diameter d₂ of approximately 28 mm for accommodating the rotary screw 40, with three radial slots 58 as well as partial ring ribs 59 of the tubular part 56, said ribs running between said radial slots. The other hinge part 54 _(a) is constructed in the same way so that, when the two parts are fitted together, the radial slots 58 in one part of the hinge 54 or 54 _(a) is capable of receiving a partial ring rib 59 of the other part of the hinge 54 _(a) or 54, respectively. These two parts 54, 54 _(a) of the hinge are held together by the rotary screw 40 that passes through their common tubular channel 57.

A wing plate 66 is inserted as the connecting tension bracket into the respective external oblong slot 60 of that hinge parts 54 or 54 _(a), respectively, that crosses with its adjacent overhang ribs 62 three screw holes 63, with a molded-on push bar 68 that forms a linear edge 67. This wing plate is secured in position with three socket head cap screws 64, which in turn then also cross the oblong slot 60 and the drill holes 65 of the push bar 68. The configuration of this wing-like connecting plate 66 resembles that of the lid of a grand piano and ends relative to the push bar 68 with a protruding semicircular tongue piece 69 that contains a passage hole 69 _(a) near the edge which forms a connection point.

FIG. 39 is an oblique view of a wing plate 66 _(a) that has, instead of the tongue piece, a straight side edge 67 _(a) that runs at an angle w₂ of, for example, 30° in relation to the free edge 67 of the plate 66 _(a). This obliquely extending side edge 67 _(a) rests against a lateral tube 72, which accommodates a hexagonal nut 73 with a push-on disk 74 having a semicircular cross section. In this case, it involves the aforementioned threaded fitting 70.

FIGS. 45 to 47 show different positions of the overhang plate 60 of a connecting member 50. In FIGS. 45 and 46, the rotary screw 40 runs at approximately right angles to the longitudinal axis E of the column 10 or more specifically the central axis M of the hinge joint 20. In FIG. 47, the longitudinal axis A of the rotary screw 40 is folded upward at an angle t of approximately 45° in relation to the central axis M.

The connecting member 50 _(a) of FIG. 48 resembles the just described connecting member 50 with the one difference that the rotary screw 40 passes through a central tubular channel 77 of the connecting member 50 _(a), which in this case is constructed as one piece. The central hinge of FIG. 37 is missing here. The connecting member 50 _(a) is constructed as a flat plate, since, instead of a pairing of two hinge halves 54 according to FIGS. 48, 49, there is a compact base plate 80 with the central tubular channel 77, the vertex e₃ of the base plate 80 being 40 mm herein, the length n being 120 mm, and the width b being 100 mm here. The distance b₁ between the two rows of screw holes 63 measures 70 mm; their distance b₂ from the adjacent longitudinal edge 61 is 15 mm in each case. The clear height h₃ of the lateral oblong slots 60 is 13 mm, a distance that matches the dimension in FIG. 42.

The drawings do not show that in this case, too, it is possible to use the described threaded fitting 70.

According to FIGS. 55 and 56, the described connecting member 50 can also be used as the connecting element for strip-like so-called keder profiles 100. Such a keder profile 100 is connected to the connecting member 50 by means of tension brackets 98, which are mounted in a rotationally limited manner at both ends. At the same time, the pins 76 pass through the keder profile 100 and the tension bracket 98, each of which is fixed in position at both ends by a safety cotter pin 75, which passes radially through the same. The pin 76 passes through both the hinge parts 54 and 54 _(a), respectively, and also a washer 39 _(a) on both sides of the tension bracket 98.

Each of the two keder profiles 100 of FIGS. 55 and 56 consists of two angle sections 102 that are molded by extrusion molding from a light metal alloy with each of these angle sections having an L-shaped cross section and in FIG. 55 forming together with a base arm 104 an overhang plate as well as two end strips 106, reaching upward at a right angle from said overhang plate at an edge. According to FIG. 57, each angle section 102, having a cross-sectional height h₈ of 50 mm herein, a cross-sectional width b₆ of approximately 80 mm, as well as a thickness f₁ of 12 mm or f₂ of 13 mm, contains a plurality of longitudinal channels 108 or 109, respectively. In addition, the base strips 104, which lie one over the other, form with the recesses 110 _(a), 111 _(a), which are also situated one over the other and are a part of the external surfaces 105 (FIGS. 55 and 57) of the base strips, a common central channel 110 having an approximately rectangular cross section and a common longitudinal channel 111 having a circular cross section.

The end strips 106 contain the passage slots 107, which cross said end strips, for the tension brackets 98 and terminate in each case with a longitudinal edge 112, into which an oblong slot 114 extends. On the other hand, said oblong slot issues from the adjacent longitudinal channel 109. This oblong slot 114 serves to accommodate a so-called keder, which is secured on the edge of an assigned textile surface. This keder has to be enveloped by the membrane, which is welded together. Then the keder of a defined strength sits rigidly and immovably on the edge of the textile surface. This keder has to transfer the forces of the transverse direction to a structural element, to the keder profile 100 in the example of FIG. 55.

FIGS. 58 to 60 show a portion of a mounting section 120, having a right angular cross section, for the angle section 102. A shaped plate 122 extends from the end strip or transverse strip 106 of said profile, said shaped plate sitting with an endwardly molded-on round bead 124 in the longitudinal channel 109 of the angle section 102. Above the longitudinal edge 112, which is semicircularly curved in the cross section, there is a second shaped bead 126 of the shaped plate 122. The center points of the two beads 124, 126 form a distance g of 8.6 mm herein, the distance g₁ of the center point Z₁ of each round bead 124 from the underside 105 of the base arm 104 of the angle section 102 measuring 44 mm herein. The distance g₂ of the center point Z₁ from the upper surface 128 of a transverse plate 130, which is molded endwardly at a right angle onto the shaped bar 122, is 56 mm herein, said transverse plate having a width e₇ of 50 mm and a thickness e₇ of 2 mm. The clear distance g₃ of the transverse plate 130 from the base strip 104 measures 85 mm; and the thickness e₈ of the shaped plate 122 is only slightly larger than the thickness e₇.

In FIGS. 61 and 62, two transverse strips of keder profiles 100 made of light metal sections are assigned to each other at a distance k₁; and in FIG. 62 the end or transverse strips 106 of their angle sections 102 are connected by spacing screws 116. In this case, the figures show two membrane webs S₁, which are clamped with an edge in a respective central channel 110 by means of an inserted profile bar 115. Two cloth strips S₂, which are laid over the angle sections 102 in order to protect them and are connected to each other on a longitudinal plate 118, terminate on the surface of the membrane webs S₁. Owing to the oblong slot 114 of the longitudinal edge 112, this longitudinal plate is positioned in the longitudinal channel 109 adjacent to this longitudinal edge and extends at a distance in parallel to the spacing screws 116.

FIG. 63 shows a device analogous to that in FIG. 56, where the keder profile 100 is provided with a housing 140. This housing has a floor plate 132 with a profile bar 135 having a circular cross section, said profile bar in the working position resting in the transverse channel 111 of the transverse strip 100. A wall plate 134 having an angular cross section is hinged to the floor plate 136 with both wall strips 136, 136 _(a) of said wall plate defining an angle w₃ of approximately 130°. In the working position, an angle section 138 is connected to the narrow wall strips 136 _(a). The free edge of said angle section also forms a profile bar 135 _(a). In the working position, this profile bar rests in the upper longitudinal channel 109 of the upper angle section 102.

FIG. 64 indicates a connecting device of two net or cloth surfaces which are not illustrated. A retaining tube 142, which is shown in sections and exhibits an external diameter q, is connected to a spaced ridge tube 144, having a significantly smaller diameter q₁, by means of three radial plates 146. U-shaped clamps 150 may be slid onto this ridge tube 144. The clamps can be secured with their bow end 148 on said ridge tube and are slid with a screw end 149 through a hole in one of the assigned angle sections 102. One of these holes is indicated at 147 in FIG. 64. Threaded nuts 41 _(a) secure the two screw ends 149 of the clamp 150 on the angle section 102, on which the net or cloth surface is secured. The result is, for example, a rigid connection between two such textile surfaces, which rest in the adjacent hole sections 145, 145 _(a) of the length c of the ridge tube 144. 

1. A load-absorbent device for introducing load forces, such as cable forces or tensioning forces of sheet-like structures, into supporting structures (10) and that comprises at least one bearing element (24, 80) which is anchored on the pertinent supporting structure (10) and to which a tension rod (40) of a load-absorbing member (36, 40) is connected, and that comprises a connecting device (50) for tensioning members (16; 98) which interacts with the tension rod (40), characterized in that the connecting device (50) has at least one connecting wing (66) which projects laterally from the longitudinal axis (A) and which forms at least one connection point (69 _(a)) which is offset to the longitudinal axis (A).
 2. The load-absorbing device according to claim 1, characterized in that the respective wing (66) is supported on the tension rod (40) to be able to swivel around the longitudinal axis (A).
 3. The load-absorbing device according to claim 1, characterized in that the connecting device (50) has two wings (66) which extend in different directions away from the longitudinal axis (A).
 4. The load-absorbing device according to claim 3, characterized in that the two wings (66) are formed by plates of the same shape and are rigidly connected to a hinge member (54, 78) which forms the swivel bearing of the pertinent wing (66) on the tension rod (40).
 5. The load-absorbing device according to claim 4, characterized in that the hinge member (78) is constructed as one piece and horizontally rigidly connects the wings (66) to one another in a common plane.
 6. The load-absorbing device according to claim 4, characterized in that the hinge member (54) is multi-part and for each wing (66) has one bearing part (54, 54 _(a)) with which the wings (66) can be swiveled around the longitudinal axis (A) independently of one another.
 7. The load-absorbing device according to claim 2, characterized in that the respective wing (66) can be swiveled around a swiveling axis (B) which is perpendicular to the longitudinal axis (A).
 8. The load-absorbing device according to claim 1, characterized in that the tension rod (40) has an external thread on which an adjusting nut (38) forms an axial safeguard of the connecting device (50).
 9. The load-absorbing device according to claim 1, characterized in that a spherical body (36) which is attached to the tension rod (40) for forming an hinge joint (20) on the bearing element (24, 80) is supported on one part of a support surface (31), which forms a spherical cap. 